On the Microlensing Optical Depth of the Galactic Bar
arXiv:astro-ph/9605030 · doi:10.1093/mnras/283.4.1197
Abstract
The microlensing probability (optical depth $Ï$) toward the Galactic center carries information about the mass distribution of the Galactic bulge/bar, so can be used to constrain the very uncertain shape parameters of the bar. We find $tau$ depends on the bar mass, radial profile, angle, axis scale lengths and boxyness by a few simple analytical formulae, which shows: (1) $Ï$ is proportional to the mass of the bar, $M$. (2) $Ï$ falls along the minor axis with a strong gradient. (3) An oblate bulge can have more optical depth than a triaxial bar if the bar angle $α>45$ degress. (4) $Ï$ is the largest if the angle $α$ and the axis ratio $y_0/x_0$ conspires so that $y_0/x_0=\tan α$. (5) At a fixed field on the minor axis but away from the center, boxy bars with a flat density profile tend to give a larger optical depth than ellipsoidal bars with a steep profile. (6) Main sequence sources should have a significantly lower (20-50\% lower) optical depth than red clump giants if main sequence stars are not observed as deep as the bright clump giants. An application to four COBE-constrained models (Dwek et al. 1994) shows most models produce optical depth $2Ï$ lower than MACHO and OGLE observed values even with both a massive bar $2.8\times 10^{10} M_\odot$ and a full disk. The high $Ï$ argues for a massive ($> 2\times 10^{10}M_\odot$) boxy bar with $y_0/x0\approx \tanα$ and $α<20$ deg and with a flat radial profile up to corotation.
28 pages including 6 postscript figures in uuencoded compressed tar file. Submitted to MNRAS